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PROBA

PROBA (Project for On-Board ) is a series of missions developed by the (ESA) to demonstrate innovative technologies, including autonomous operations and precision , while also supporting and solar research. Initiated in the early as part of ESA's General Support Technology Programme, the PROBA series aims to validate new engineering solutions for future space missions, such as advanced attitude control, radiation-hardened components, and inter-satellite communication. The early missions utilized cost-effective micro-satellite platforms under 150 kg, whereas PROBA-3 employs a pair of larger satellites for . These missions have pioneered full , allowing satellites to perform tasks like orbit adjustments and with minimal ground intervention, thereby reducing operational costs and enhancing reliability for deep-space and Earth-orbiting applications. The flagship missions include PROBA-1, launched on 22 October 2001 aboard an Ariane-5 rocket, which served as the first technology demonstrator and later transitioned to an operational Earth observation role using its Compact High Resolution Imaging Spectrometer (CHRIS) for hyperspectral imaging of terrestrial surfaces; PROBA-V, launched on 7 May 2013 on a Vega rocket, which focused on global vegetation monitoring to bridge the gap between SPOT-Vegetation and Sentinel-3 missions; PROBA-2, launched on 2 November 2009 as a secondary payload on a Vega rocket, focused on solar observation and space weather monitoring with instruments like the Sun Watcher using Active Pixel System Observer and X-ray Imaging System (SWAP) and the Lyman Alpha Radiometer (LYRA), achieving over 15 years of continuous data collection on solar activity; and the most recent, PROBA-3, launched on 5 December 2024 aboard India's PSLV-XL rocket, consists of two satellites flying in precise formation to create artificial solar eclipses, enabling unprecedented study of the Sun's corona through the Coronagraph Instrument (ASPIICS) and testing metrology for future missions like asteroid deflection. By November 2025, PROBA-3 had successfully demonstrated formation flying with millimeter accuracy, marking a milestone in ESA's technology roadmap. Collectively, the PROBA missions have exceeded expectations in longevity—PROBA-1 operated for over 24 years—and technological impact, influencing designs for subsequent ESA programs like the Earth Explorers and planetary defence initiatives, while contributing valuable datasets to , , and studies.

Programme Overview

History and Development

The PROBA (Project for On-Board ) programme was initiated in the late 1990s under the European Space Agency's (ESA) General Support Technology Programme (GSTP), which had been established in to advance key space technologies. It emerged as a response to the growing demand for miniaturized satellites capable of high levels of autonomy, enabling cost-effective in-orbit demonstrations of innovative systems for future missions. Work on the first mission, PROBA-1, began in mid-1998, marking the start of a series focused on validating new technologies in a low-risk, agile development framework. Key collaborators in the programme's development were centered in Belgian industry, with Verhaert Space (now QinetiQ Space Belgium) serving as the prime contractor for PROBA-1 and leading a consortium that included contributions from other European firms specializing in satellite subsystems. This Belgian-led effort reflected strong national involvement, leveraging expertise in small satellite design to support ESA's objectives. The programme's funding came primarily from ESA's GSTP, supplemented by significant national contributions from Belgium, which helped keep development costs low while fostering industrial competitiveness across Europe. The development timeline progressed rapidly for its era: the PROBA-1 contract was awarded in 1999, culminating in a 2001 launch after just three years of development. PROBA-2 followed with its contract in 2006 and launch in 2009, building on lessons from the first mission. PROBA-V advanced in 2010 with Belgian funding enabling full development, leading to a 2013 launch. PROBA-3 was approved in 2011 under GSTP, but encountered multiple delays due to technical challenges and the , postponing its launch until December 2024. Over time, the PROBA programme evolved from demonstrating autonomy and control technologies in single-satellite platforms with PROBA-1 and PROBA-2, to incorporating capabilities in PROBA-V, and ultimately advancing to multi-satellite in PROBA-3, which tests precise coordination between two for enhanced mission flexibility. This progression has positioned PROBA as a cornerstone for ESA's low-cost technology validation strategy, influencing subsequent initiatives.

Objectives and Innovations

The PROBA programme, initiated by the (ESA) under its General Support Technology Programme (GSTP), primarily seeks to demonstrate on-board autonomy for attitude and orbit control, fault detection, isolation, and recovery (FDIR), as well as streamlined operations tailored to small satellites. This focus addresses key challenges in reducing ground intervention and operational costs for future missions, enabling to manage routine tasks, , and recovery autonomously. A central innovation of the programme is the PROBA satellite platform, designed as a modular and versatile bus for in-orbit technology validation, incorporating miniaturized components such as advanced star trackers for precise attitude determination, compact reaction wheels for , and integrated GPS receivers for . These elements support high levels of self-sufficiency, with onboard software handling , scheduling, and failure reconfiguration without constant ground oversight. The platform's emphasis on commercial-off-the-shelf (COTS) and robust processing units further enhances its adaptability for diverse demonstration missions. While technology demonstration remains the core priority, secondary scientific aims involve leveraging the platforms for —such as vegetation monitoring and land use tracking—and studies, providing real-mission contexts to test in dynamic environments. Key concepts include progressive capabilities, from semi-autonomous maneuvers to comprehensive FDIR that isolates faults and initiates recovery actions independently, minimizing disruptions. Across the programme, satellites are targeted for operational lifetimes of 2-5 years to validate long-term reliability, yet many exceed these benchmarks through resilient design, exemplified by PROBA-1's extension beyond two decades of active service. This durability underscores the programme's success in fostering robust, efficient architectures.

PROBA-1

Design and Launch

PROBA-1 is a small, cube-shaped with dimensions of 60 cm × 60 cm × 80 cm and a launch mass of 94 , including 25 for payloads. The structure uses an aluminum platform with body-mounted solar panels generating up to 90 W of power, stored in a 36-cell pack. It features no dedicated system, relying on magnetic torquers and reaction wheels for attitude control. The employs a dual-computer setup: an ERC32-based main processor for and a TSC21020 for payload operations. Attitude determination uses a for high accuracy (150 arcseconds absolute pointing, 10 arcseconds stability over 10 seconds), supplemented by GPS and gyroscopes. Communication occurs via S-band transponders, with passive thermal control to maintain operations in . PROBA-1 launched on 22 October 2001 at 06:53 UTC as a secondary on the Indian Space Research Organisation's (ISRO) PSLV-C3 rocket from the in , . It was deployed into a at a mean altitude of 615 km, with an inclination of 97.9° and an of 96.97 minutes. This orbit supports passes near the 10:30 descending node, though the orbit has since drifted.

Mission and Operations

The primary objectives of PROBA-1 were to demonstrate autonomous operations, advanced attitude control, and new technologies as part of ESA's General Support . Originally planned for a two-year , it transitioned to an operational role, acquiring hyperspectral images and monitoring space environment effects. The mission pioneered full onboard , enabling the to perform maintenance, collision avoidance, scheduling, and data compression with minimal ground intervention. Key instruments include the Compact High Resolution Imaging Spectrometer (), a hyperspectral imager weighing 14 kg that captures data in 62 spectral bands from 400–1050 nm at 17–34 m resolution across a 13 km swath; the High Resolution Camera (HRC) for 8 m panchromatic imaging; the Debris In-orbit Evaluator (DEBIE) for micrometeoroid detection; and the Standard Radiation Environment Monitor (SREM) for particle flux measurements. Operations are managed from ESA's Redu Space Services Centre in , with occasional support from the (ESOC) in , . The satellite supports agile pointing up to ±55° along-track and ±36° across-track for targeted observations. As of December 2022, imaging ceased due to instrument aging, but the spacecraft remains active for software testing and algorithm validation. As of November 2025, PROBA-1 continues limited operations in a drifting , with plans for active deorbit by ESA's mission targeted for 2028.

Key Achievements and Technologies

PROBA-1 has far exceeded its design life, operating for over 24 years as of November 2025, making it ESA's longest-serving mission. It acquired more than 20,000 images, supporting over 60 international investigators in applications like vegetation mapping, coastal monitoring, and climate studies, while contributing to and datasets. The mission demonstrated reprogrammable software, allowing in-flight updates to handle anomalies, and validated commercial-off-the-shelf components , including the star tracker-based system without or Sun sensors. Technological innovations include the first use of Li-ion batteries on an ESA mission, high-agility pointing for multi-angle , and that reduced ground operations costs by up to 70%. SREM data has advanced modeling, and DEBIE provided early insights into orbital risks. These achievements influenced subsequent PROBA missions and ESA programs like Earth Explorers, proving the viability of low-cost, microsatellites for operational . As of November 2025, the satellite supports ongoing tests for future features and is designated as the target for ESA's first active removal demonstration via ClearSpace-1.

PROBA-2

Design and Launch

PROBA-2 is a single with a of 130 and dimensions of 0.6 m × 0.6 m × 0.8 m, featuring a box-shaped structure and two deployable panels that generate up to 110 W of , supported by a 16.5 Ah . The attitude and (AOCS) provides three-axis stabilization using four reaction wheels, magnetorquers, a achieving 5 arcsecond accuracy over 10 seconds, sun sensors, and GPS receivers for precise navigation. Propulsion is handled by a xenon resistojet for maintenance, with a monopropellant system for initial adjustments. The satellite carries four instruments for scientific and purposes: the Sun Watcher using Active Pixel System Observer and Imaging System (SWAP), a (EUV) imager operating at 17.4 nm to monitor the solar corona and activity; the Lyman Alpha Radiometer (), measuring in four UV channels; the Double Stage (DSLP) for ionospheric density; and the Thermal Plasma Measurement Unit (TPMU) for monitoring. PROBA-2 launched on 2 2009 at 18:23 UTC as a secondary alongside the Soil Moisture and Ocean Salinity (SMOS) , aboard a Rockot launch vehicle from in . It was inserted into a Sun-synchronous dawn-dusk at an altitude of 720 km, with an inclination of 98.2° and a of about 1° per day, enabling near-continuous interrupted by seasonal eclipses of up to 18 minutes from to .

Mission and Operations

The PROBA-2 mission objectives include demonstrating 17 innovative technologies for future ESA satellites, such as advanced onboard with the processor-based Advanced Data and Power Management System (ADPMS), fiber-optic gyroscopes, and miniaturized star trackers, while conducting scientific observations of solar activity and phenomena like coronal mass ejections and solar flares. Following launch, the satellite underwent commissioning, with nominal operations beginning in December 2009. The planned two-year mission was extended multiple times due to successful performance: first to December 2012, then to 2018 under the programme, and continuing thereafter. As of November 2025, PROBA-2 remains operational, providing real-time data on solar variability and supporting missions like . Operations emphasize autonomy, with the satellite performing attitude maneuvers and data collection with minimal ground intervention, controlled primarily from the Redu Space Services Centre in and ESA's in , . Payload activities focus on near-continuous imaging by SWAP (up to 1 image every 150 seconds) and irradiance measurements by , complemented by in-situ plasma data from DSLP and TPMU during orbit. The mission experiences periodic eclipses but maintains high data return rates.

Key Achievements and Technologies

PROBA-2 has achieved over 16 years of continuous operation as of November 2025, far exceeding its nominal duration and delivering a valuable dataset on solar cycles, including the onset of Solar Cycle 25 in 2020 and observations of major events such as the Mercury transit on 11 November 2019 and numerous coronal mass ejections. Its SWAP instrument has provided high-resolution EUV images of the solar atmosphere, contributing to space weather forecasting and solar physics research, while LYRA's measurements have advanced understanding of solar irradiance variations affecting Earth's climate and technology. Key technologies demonstrated include the POCKET+ compression algorithm for efficient image downlink, high-capacity lithium-ion batteries qualified for space use, the xenon resistojet propulsion system for precise orbit control, and autonomous navigation capabilities using GPS and star trackers, which have informed designs for subsequent ESA missions like and . The mission's integration of 17 experimental components from ten European countries and has validated low-cost, rapid-development approaches for microsatellite platforms, enhancing ESA's technological roadmap for autonomous operations in .

PROBA-V

Design and Launch

PROBA-V is a single with a launch mass of 140 and dimensions of approximately 0.8 m × 0.8 m × 1.2 m, built by Space in on ESA's PROBA platform. The features a three-axis stabilized attitude using star trackers, GPS receivers, reaction wheels, and magnetotorquers for precise pointing, with no onboard propulsion for orbit maintenance. Power is provided by deployable solar panels generating up to 200 W, supplemented by lithium-ion batteries. The primary payload is the Vegetation (VGT) instrument, a multispectral pushbroom imager consisting of three cameras: two for visible and near- (VNIR) bands at 100 m and one for short-wave (SWIR) at 200 m . The VGT covers four VNIR bands ( at 0.459 μm, red at 0.655 μm, NIR1 at 0.665 μm, NIR2 at 0.846 μm) and one SWIR band (1.610 μm), with a total swath width of 2,250 km and a of 103°. Additional technology demonstrations include the HERMOD laser communication terminal and an energetic particle detector. The satellite launched on 7 May 2013 at 03:06 UTC as the primary payload on the inaugural VV01 rocket from the in , . It was inserted into a at 820 km altitude, 98.7° inclination, with a local time of ascending at 10:30, and an orbital period of 101 minutes, enabling daily global coverage between 35°N and 56°S latitudes.

Mission and Operations

PROBA-V's primary objective was to monitor global vegetation cover and land use changes as a successor to the SPOT-VGT mission, providing multispectral imagery for applications in , , , and . The VGT instrument acquired data in pushbroom mode, achieving 100 m over a 1,000 km swath for VNIR and 2,000 km for SWIR, with full global coverage every two days at coarse resolution (300 m effective) and daily revisits for mid-latitudes. Data supported the Copernicus Global Land Service and other initiatives for estimation, assessment, and management. Following launch, a six-month commissioning until December 2013 verified instrument performance, attitude control, and data downlink. Nominal operations ran from 2014 to June 2020, delivering over 100,000 images annually to ground stations. Due to gradual orbital drift affecting optimal sun illumination, the operational ended on 30 June 2020, transitioning to an experimental focusing on higher-resolution (100 m) acquisitions over and Africa until October 2021. The mission was fully decommissioned on 31 October 2021 after passivation and deorbiting maneuvers to comply with mitigation guidelines. Ground operations were managed by ESA's (ESOC) in , , with data processing and distribution handled by the Flemish Institute for Technological Research (VITO) in . As of November 2025, the full dataset archive remains available for , supporting over 1,800 user teams worldwide.

Key Achievements and Technologies

PROBA-V successfully demonstrated the feasibility of a miniaturized satellite platform for operational , providing continuous global data from 2013 to 2020 that enhanced climate modeling, agricultural forecasting, and assessments. The mission generated petabytes of imagery, cross-validated with satellites, and contributed to products like the 300 m Vegetation Products for the Copernicus program, aiding in real-time monitoring of events such as wildfires and floods. Its longevity exceeded the planned 2.5–5 years, operating for over eight years and delivering high-quality data until orbital constraints ended routine imaging. Technologically, PROBA-V advanced onboard autonomy with autonomous data prioritization and compression algorithms, reducing ground intervention by up to 80%. The VGT instrument showcased a compact, high-performance spectrometer design, influencing future missions like the Biomass satellite. Other demonstrations included the first in-orbit test of a laser communication system (HERMOD) for high-speed data relay and radiation monitoring tools, validating components for deep-space applications. The mission's legacy includes open-access data reprocessed in 2022–2023, ensuring long-term usability for scientific analysis as of November 2025.

PROBA-3

Design and Launch

PROBA-3 consists of two distinct satellites designed to operate in precise formation: the and the Occulter Spacecraft (OSC). The CSC, with a wet mass of approximately 340 kg, hosts the primary , while the OSC, weighing about 200 kg, carries the occulter mechanism; together, they form a combined system mass of around 540 kg. Inter-satellite communication and ranging are facilitated through (RF) links in the S-band and systems, enabling real-time relative positioning and data exchange between the two platforms. The platforms incorporate cold gas thrusters for fine formation control on the OSC and a monopropellant hydrazine system for larger orbital adjustments on the CSC. Navigation relies on GPS receivers for coarse positioning during apogee phases, star trackers for attitude determination, and additional visual sensors including cameras, LEDs, and shadow positioning sensors to achieve centimeter-level relative accuracy. The CSC integrates the ASPIICS (Association of Spacecraft for Polarimetric Imaging Investigation of the Corona of the Sun) coronagraph, a telescope optimized for imaging the solar corona, while the OSC features a 1.4-meter diameter occulter disk deployed on an extendable boom to precisely block the solar disk, creating extended artificial eclipses up to six hours in duration. The mission launched on December 5, 2024, at 10:34 UTC aboard an PSLV-XL rocket from the in , . The satellites were deployed into a highly elliptical with a perigee of 600 km, an apogee of 60,530 km, an inclination of 59°, and an of approximately 19.7 hours, selected to support long-duration sequences primarily at apogee where gravitational perturbations are minimized.

Mission and Operations

The PROBA-3 mission primarily aims to demonstrate precise technologies using two coordinated satellites, the Coronagraph Spacecraft (CSC) and the Occulter Spacecraft (OSC), while enabling in-orbit to observe the Sun's inner . Launched on December 5, 2024, aboard an PSLV rocket, the satellites operate in a highly elliptical with a period of approximately 19.7 hours and an apogee of 60,530 km, allowing passage through Earth's radiation belts for relevant technology testing. Following launch, the commissioning phase began in December 2024, with the satellites remaining stacked until their successful separation on January 15, 2025, at an altitude of about 60,000 km. During this initial stage, ground teams activated subsystems, verified systems including cold gas and chemical thrusters, and conducted preliminary relative positioning maneuvers to establish a baseline separation. tests commenced in March 2025, with the first autonomous acquisition achieved on March 27, featuring maneuvers ranging from 25 m to 250 m to validate millimeter-precision control. Operational slots for occur for up to six hours per orbit, during which the satellites align precisely— with the OSC positioned 150 m ahead of the —to block solar disk light and facilitate uninterrupted coronal imaging. Autonomous relative navigation relies on onboard vision-based sensors and systems to maintain formation without continuous ground intervention. Payload operations center on the ASPIICS (Association of Spacecraft for Polarimetric Imaging Investigation of the Corona of the Sun) instrument aboard the , which captures high-resolution images of the inner solar corona by leveraging the OSC's occulter to suppress from the solar disk. This configuration simulates a total , enabling observations otherwise limited by external designs. Additional technology demonstrations include instruments for monitoring electron spectra in Earth's radiation belts, such as the 3D Energetic Electron Spectrometer (3DEES), to assess environmental effects on satellite components during apogee passages. The nominal mission duration is two years, ongoing as of November 2025, with routine operations divided into phases focused on formation , , and periodic reconfiguration tests. Ground support is provided by ESA's (ESOC) in , , for overall mission control and ground station interfacing, alongside the primary mission operations center at the Redu Space Services Centre in for handling and command uplink.

Key Achievements and Technologies

PROBA-3 has achieved millimetre-precision between its two spacecraft, the and the Occulter, marking the world's first successful demonstration of such technology in orbit. This precision, maintained for several hours during autonomous operations, was accomplished in May 2025 using the Fine Lateral and Longitudinal (FLLS), a -based system that enables relative positioning down to the level. The mission's suite, including inter-satellite links and corner cube retroreflectors, provides continuous relative position data essential for aligning the Occulter to block the Sun's disk precisely. Scientifically, PROBA-3's ASPIICS coronagraph has delivered unprecedented imaging of the inner solar corona, extending observations from 1.1 to 3 solar radii— a range previously inaccessible due to internal occulter limitations in traditional coronagraphs. These observations, enabled by the formation-flying configuration that simulates prolonged solar eclipses, contribute valuable data for modeling solar wind dynamics and improving space weather forecasts. The first such images were released in June 2025, showcasing the greenish inner corona and highlighting the mission's ability to capture fine details over extended durations. Key milestones include the resolution of launch delays originally planned for , which were addressed through iterative testing and , culminating in a successful liftoff on , 2024, via India's PSLV rocket. Post-launch, initial orbit adjustments were performed using chemical thrusters to reach the , followed by validation of the 's cold gas and chemical propulsion systems for fine maneuvering and station-keeping. By November 2025, the had conducted multiple long-duration autonomous formations, demonstrating the reliability of these for future distributed systems.

Legacy and Impact

Technological Advancements

The PROBA series has pioneered advancements in , evolving from basic fault detection, isolation, and recovery (FDIR) systems in PROBA-1 to sophisticated millimetre-level formation control in PROBA-3. PROBA-1 introduced autonomous navigation and attitude control using star trackers and GPS, enabling operator-free passes and minimal ground intervention, which significantly reduced operational overhead compared to traditional missions. Subsequent missions built on this foundation: PROBA-2 incorporated advanced processors like the for onboard decision-making, while PROBA-V enhanced FDIR with automatic anomaly handling and land-sea masking for efficient . PROBA-3 represents the pinnacle, demonstrating autonomous with millimetre precision over 150 m distances using relative GPS and sensors, allowing the two satellites to maintain alignment without real-time ground guidance. In June 2025, PROBA-3 captured its first images of the solar corona, validating the formation flying for scientific observations. Across the series, these developments have reduced ground operations requirements by up to 80%, shifting control to onboard systems for greater efficiency and resilience. Platform innovations in the PROBA missions emphasize and robustness, facilitating the shift toward small-satellite constellations. Each PROBA features a compact bus under 1 m³ in volume and around in mass, such as PROBA-1's 94 design with agile 25° across-track tilting capability using reaction wheels and magnetotorquers for 1 arc-minute pointing accuracy. These miniaturized platforms reuse heritage components, like the advanced data and systems in PROBA-V with 100 Gbit mass memory and LEON2-FT processors. Radiation-hardened elements ensure longevity, exemplified by PROBA-1's solar cells and , which supported over 20 years of operation in —far exceeding the initial 2-year design life—while PROBA-2 validated radiation-tolerant propulsion and digital sun sensors. This approach has enabled cost-effective, scalable architectures for future distributed systems. Payload technologies across the PROBA series have validated diverse, compact instruments for and . PROBA-1's hyperspectral Compact High Resolution Spectrometer () captured images in up to 62 spectral bands at 17–34 m resolution, demonstrating agile . PROBA-2 advanced solar monitoring with (EUV) instruments like the Sun Watcher using Active Pixel System (SWAP) for and Lyman-alpha Radiometer (LYRA) for UV irradiance measurements. PROBA-V introduced wide-swath visible and near-infrared (VNIR) capabilities via its instrument, providing 100 m resolution over 2250 km swaths in blue, red, , and shortwave infrared bands for global vegetation mapping. PROBA-3 innovates with occulter-based , using a 1.4 m disc on the Occulter satellite to cast a precise shadow on the Coronagraph satellite's , enabling continuous observation of the Sun's inner without interference. The PROBA missions have collectively validated numerous technologies, while maintaining cost efficiency with relatively low-cost missions through design-to-cost principles and industrial collaboration. These validations have established benchmarks for , , and integration, proving the viability of low-cost platforms for high-impact .

Influence on Future Missions

The PROBA series has significantly influenced subsequent ESA missions through the reuse of its software, particularly in and systems (AOCS). The AOCS software developed for PROBA-V serves as the baseline for the mission, enabling enhanced operational in Earth platforms within the . Similarly, the onboard concepts pioneered by PROBA, including automated navigation and task execution, have informed the design of interplanetary missions where reduced ground intervention is critical for long-duration operations. PROBA-3's demonstration of precise technology, achieving separations as fine as 150 meters between satellites, paves the way for advanced multi-spacecraft configurations in future ESA efforts, such as potential applications in constellation-based observations or missions requiring coordinated swarms like those explored in concepts for federations. This capability supports upcoming initiatives involving distributed systems, reducing complexity and costs for operations in Earth orbit and beyond. Additionally, the PROBA programme's emphasis on low-cost technology demonstrations has shaped standards for and nanosatellite missions, promoting agile development and across international space efforts. Operationally, PROBA-V's vegetation monitoring data has been seamlessly integrated into the , providing continuity for global analysis and supporting services like and climate monitoring. In terms of , PROBA-1's planned deorbiting by the mission, with launch scheduled for late 2026 (as of November 2025), marks a milestone in active debris removal, targeting an uncooperative object to demonstrate end-of-life disposal technologies essential for future orbital environments. Looking ahead, the PROBA legacy extends to emerging demonstrations like OPS-SAT, which builds on PROBA's in-orbit paradigm to validate advanced operations software, and Φ-sat, where onboard for draws from PROBA's foundational work in self-managing systems. While no formal extension of the PROBA series has been announced, its proven model for affordable innovation continues to inspire similar low-risk, high-reward missions within ESA's portfolio.

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  33. [33]
    ESA - OPS-SAT - European Space Agency
    ESA's OPS-SAT mission came to an end during the night of 22—23 May 2024 (CEST). A flying laboratory, ESA's OPS-SAT is the first of its kind, with the sole ...Missing: extension phi-